Active clinical trials for "Paresis"

The study was designed to evaluate the impact of a novel kinematic biofeedback system - SWORD - in the motor performance of patients after stroke. The SWORD system combines inertial motion trackers and a mobile app, allowing digitization of patient motion and providing real-time audiovisual biofeedback. The investigators hypothesize that the biofeedback feedback provided by the SWORD system improves patient performance, defined as an increase in the number of correct movements. The design of the study is a cross-over randomized clinical trial. Patients will be randomized into two groups. Both will perform two separate sessions consisting of one exercise - shoulder flexion with elbow flexion at 90 degrees - for 4 minutes in both experimental settings: with and without biofeedback. Group 1 will perform the exercise with biofeedback first and without biofeedback after, with an interval >24h. Group 2 will perform the exercise in the opposite order. The SWORD system will be used to record movement data in both sessions, but the feedback was only active in one of them.

This research project will investigate neurofeedback training in stroke rehabilitation during which patients receive feedback in real time from their brain activity measured with ElectroEncephaloGraphy (EEG). The investigators hypothesize that the feedback training allows to internally stimulate brain motor networks in order to promote functional recovery of the hand.

The purpose of this study is to test the hypothesis that early independent adaptive bimanual-to-unimanual training of arm and hand movements, assisted with specially designed mechanical devices: the mirrored motion bimanual arm trainer (m2 BAT), will improve motor control and function in patients with post-stroke hemiparesis.

This is a single-blinded randomized control trial aiming to explore the use of immersive virtual reality (VR) training in conjunction with real-life tasks therapy in 75 first time stroke patients with upper limb weakness.

Aerobic treadmill exercise has been shown to improve walking, cardiovascular fitness and thereby risk factor profiles in chronic stroke patients (Macko et al., Stroke 2005). The proposed project is a randomized controlled trial in geriatric stroke patients with chronic disabilities to investigate potential mechanisms of treadmill therapy. The hypothesis is tested that 3-months of aerobic treadmill exercise induces structural brain plasticity and reorganization. The outcome measures are walking ability, gait pattern, cardiovascular fitness and brain morphology. This study will elucidate fundamental mechanisms of brain adaptations linked to task-repetitive aerobic lower extremity exercise. These mechanisms will not only lead to a better understanding but may also help to identify predictors of treatment response. 40 patients aged over 60 years with lower extremity paresis after a first-ever clinical stroke longer than 6 months prior to study inclusion will be recruited from: 1) The Geriatric Rehabilitation Clinic at the Robert-Bosch Hospital in Stuttgart 2) the Dept of Neurology, University Hospital in Tübingen. Subjects will be randomized to 3 months progressive graded aerobic treadmill exercise training (TAEX; 3 times/week, duration 10-45 min) or an attention control group (CON). Because we expect that localization and size of stroke affect therapy outcomes, stratified randomization will be used to balance entry into groups. We hypothesize that 3 months of treadmill gait training but not conventional care leads to improvements of cardiovascular fitness and gait and to brain reorganization (structural plasticity) in regions in which functional adaptations have been demonstrated using fMRI in previous studies. The specific aims are: To assess reorganization by comparing cortical thickness, cortical density and fiber tract morphology before (time point 0), and after therapy (3 months) using T1-weighted 3D-MPRAGE images, voxel based morphometry and diffusion tensor imaging. To correlate brain reorganization with improvements in walking velocity, and analysis of gait patterns (parameters, swing time, stance time, gait symmetry). To correlate brain reorganization with location and size of the index stroke lesion and of diffuse white matter damage (subcortical vascular encephalopathy). Lesion and white matter damage will be evaluated based on T2-weighted FLAIR sequences.

The objective of this pilot randomized controlled single blinded, parallel-group study is to detect change of the Action Observation (AO) and Repetitive Task Practice (RTP) combined practice schedule on upper limb motor impairment outcomes in chronic, moderately impaired stroke survivors.

The purpose of this study is to evaluate the clinical results produced by a training protocol with the new device for cervical treatment (CDAT) and the conventional training protocol (CT) versus a control group (C) in subjects with cervical deep muscle strength deficit and mild neck disability.

The aim of the study is to investigate whether the combination of bihemispheric ("dual") transcranial direct current stimulation (tDCS) and motor training on 5 consecutive days facilitates motor recovery in chronic stroke. Results will be compared to a matched group of patients undergoing anodal tDCS as well as a control group receiving sham tDCS. Functional and structural magnetic resonance imaging (MRI) before/after the intervention and during a 3 month follow-up will help investigating neural correlates of expected changes in motor function of the affected upper extremity.

The aim of this project is to clinically evaluate a novel robot-assisted therapeutic approach to train sensorimotor hand function after stroke. It combines the profound experience of the clinic Hildebrand in neurocognitive therapy - involving brain and mind in the task and training both the motor and the sensory system - with the advanced haptic robotic technology of the Rehabilitation Engineering Lab at the Swiss Federal Institute of Technology Zurich (ETH Zurich), allowing unmet interaction with the hand through the simulation of virtual objects with various mechanical properties. In a randomized controlled clinical trial, 10 sub-acute stroke patients will receive four weeks of robotic therapy sessions, integrated seamlessly into their daily rehabilitation program, while 10 other patients will receive conventional therapy. The investigators will assess baseline performance in an initial clinical and robotic assessment, with another assessment at the end of the four-week period, and in follow-ups four weeks and six months later. The contents of the patient-tailored robotic therapy sessions will match those of the conventional therapy as closely as possible. This study will demonstrate the feasibility of including robotic therapy of hand function into the daily rehabilitation program, and investigate the acceptance from patients and therapists. The investigators expect increased training intensity during the robotic therapy session compared to conventional sessions with similar contents, as well as novel insights into the recovery process of both the motor and the sensory system during the four weeks of therapy, through advanced robotic assessments integrated into the training sessions. This project is a first step towards making such robotic therapy available to patients as integration into the conventional individual therapy program (e.g. for self-training), and towards transferring this technology to the home environment.

Is a unique tele-rehabilitation service directed at treating upper limb weakness due to stroke feasible to provide at Mayo Clinic and are the individuals with stroke and the clinicians providing the care satisfied with the process?